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Intellectual Property Issues Cited as hampering Drug Development 
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Report to Congressional Requesters: 

United States Government Accountability Office: 

GAO: 

November 2006: 

New Drug Development: 

Science, Business, Regulatory, and Intellectual Property Issues Cited 
as Hampering Drug Development Efforts: 

New Drug Development: 

GAO-07-49: 

GAO Highlights: 

Highlights of GAO-07-49, a report to congressional requesters 

Why GAO Did This Study: 

Drug development is complex and costly, requiring the testing of 
numerous chemical compounds for their potential to treat disease. 
Before a new drug can be marketed in the United States, a new drug 
application (NDA), which includes scientific and clinical data, must be 
approved by the Food and Drug Administration (FDA). Recent scientific 
advances have raised expectations that an increasing number of new and 
innovative drugs would soon be developed to more effectively prevent, 
treat, and cure serious illnesses. However, industry analysts and the 
FDA have reported that new drug development, and in particular, 
development of new molecular entities (NMEs)—potentially innovative 
drugs containing ingredients that have never been marketed in the 
United States—has become stagnant. 

GAO was asked to provide information on (1) trends in the 
pharmaceutical industry’s reported research and development expenses as 
well as trends in the number of NDAs submitted to, and approved by, 
FDA; and (2) experts’ views on factors accounting for these trends and 
their suggestions for expediting and enhancing drug development. GAO 
analyzed data from FDA on all 1,264 NDAs submitted to the agency from 
1993 through 2004. GAO also convened a panel of experts and interviewed 
other drug development experts and analysts to identify factors 
affecting, and suggestions for enhancing, drug development. 

What GAO Found: 

Although the pharmaceutical industry reported substantial increases in 
annual research and development costs, the number of NDAs submitted to, 
and approved by, FDA has not been commensurate with these investments. 
From 1993 through 2004, industry reported annual inflation-adjusted 
research and development expenses steadily increased from nearly $16 
billion to nearly $40 billion—a 147 percent increase. In contrast, the 
number of NDAs submitted annually to FDA increased at a slower rate— 38 
percent over this period. Similarly, the number of NDAs submitted to 
FDA for NMEs increased by only 7 percent over this period. FDA approved 
most NDA applications—76 percent overall, but the numbers of NDAs and 
NDAs for NMEs it approved annually have generally been declining since 
1996. 

Figure: Research and Development Expenses, Total NDA, and NDA for NME 
Submissions, 1993-2004: 

[See PDF for Image] 

Source: HAO analysis of PhRMA and FDA data. 

[End of Figure] 

According to experts, several factors have hampered drug development. 
These include limitations on the scientific understanding of how to 
translate research discoveries into safe and effective drugs, business 
decisions by the pharmaceutical industry, uncertainty regarding 
regulatory standards for determining whether a drug should be approved, 
and certain intellectual property protections. These factors have been 
cited as affecting the number of drugs developed, the cost and length 
of the drug development process, as well as the types of drugs being 
produced. To address these issues, experts offered suggestions 
including increasing the number of scientists who can translate drug 
discoveries into effective new medicines and allowing conditional 
approval of certain drugs based on shorter clinical trials using fewer 
numbers of patients. In its comments on a draft of this report, the 
Department of Health and Human Services provided clarifications, which 
GAO incorporated as appropriate. 

[Hyperlink, http://www.gao.gov/cgi-bin/getrpt?GAO-07-49]. 

To view the full product, including the scope and methodology, click on 
the link above. For more information, contact 
Leslie G. Aronovitz at aronovitzl@gao.gov or (312) 220-7600. 

[End of Section] 

Contents: 

Letter: 

Results in Brief: 

Background: 

Drug Development Trends Are Not Commensurate with Research and 
Development Expenditures: 

Experts Identified Factors Contributing to Declining Productivity in 
Drug Development and Offered Suggestions for Improvement: 

Concluding Observations: 

Agency Comments: 

Appendix I: Scope and Methodology 75: 

Appendix II: National Academy of Sciences Expert Panel Participants 82: 

Appendix III: Comments from the Department of Health and Human Services 
85: 

Appendix IV: GAO Contacts and Staff Acknowledgments 86: 

Tables: 

Table 1: Ranking of Innovative Potential of NDAs Using Chemical Type 
and Therapeutic Potential Classifications 34: 

Figures: 

Figure 1: The Drug Discovery, Development, and Review Process 20: 

Figure 2: FDA Classification of NDAs by Chemical Type and Therapeutic 
Potential 22: 

Figure 3: IND Submissions, 1986-2005 29: 

Figure 4: Research and Development Expenses (Constant 2004 Dollars), 
Total NDA, and NDA for NME Submission Trends, 1993-2004 31: 

Figure 5: Proportion of 1,264 NDAs Submitted by Innovation Potential, 
1993-2004 35: 

Figure 6: Percent of NDAs Submitted that were NMEs, 1993-2004 35: 

Figure 7: Percent of NDAs Submitted that were Priority NMEs, 1993-2004 
36: 

Figure 8: Status as of September 2005 for the 1,264 NDAs Submitted, 
1993-2004 38: 

Figure 9: Average Approval Times as of September 2005 for 961 Priority 
and Standard NDAs Submitted and Approved, 1993-2004 40: 

Figure 10: Proportion of 961 NDAs Submitted and Approved by Innovation 
Potential 42: 

Figure 11: Total NDA and NDA for NME Approvals, 1993-2005 43: 

Abbreviations: 

AAMC: Association of American Medical Colleges: 
FDA: Food and Drug Administration: 
HHS: Department of Health and Human Services: 
IND: investigational new drug application: 
NAS: National Academy of Sciences: 
NDA: new drug application: 
NME: new molecular entity: 
PDUFA: Prescription Drug User Fee Act: 
PhRMA: Pharmaceutical Research and Manufacturers of America: 

[End of section] 

United States Government Accountability Office: 
Washington, DC 20548: 

November 17, 2006: 

The Honorable Edward M. Kennedy: 
Ranking Minority Member: 
Committee on Health, Education, Labor and Pensions: 
United States Senate: 

The Honorable Henry A. Waxman: 
Ranking Minority Member: 
Committee on Government Reform: 
House of Representatives: 

The Honorable Richard J. Durbin: 
United States Senate: 

Before a new drug can be marketed in the United States, it must be 
approved by the Food and Drug Administration (FDA), an agency within 
the Department of Health and Human Services (HHS). To gain approval, 
drug sponsors[Footnote 1] must submit a new drug application (NDA) to 
FDA containing scientific and clinical data. FDA reviews the NDA to 
determine whether the new drug is safe and effective for its intended 
use. The submission of an NDA typically follows a long period of 
research and development. To develop a new drug, researchers and 
scientists identify and test numerous chemical compounds for their 
potential to treat disease. On average, drug sponsors can spend over 13 
years studying the benefits and risks of a new compound, and several 
hundred millions of dollars completing these studies before seeking 
FDA's approval. About 1 out of every 10,000 chemical compounds 
initially tested for their potential as new medicines is found safe and 
effective, and eventually approved by FDA, making the drug discovery 
and development process complex, time consuming, and costly. Although 
high costs and failure rates make drug discovery and development risky, 
creating a safe and effective new drug can be rewarding for both the 
sponsor and the public. A highly successful new drug can generate 
significant annual sales, and can provide cures or help treat the 
symptoms of diseases and illnesses affecting millions of people. 

Significant scientific advances have raised new hope for the 
prevention, treatment, and cure of serious illnesses. For example, the 
decoding, or sequencing of the human genome, advances in medical 
imaging, and new technologies that enable drug researchers to rapidly 
synthesize numerous compounds, created expectations that the 
pharmaceutical industry would soon be producing an increasing number of 
new and innovative drugs to more effectively treat disease. However, 
over the past several years it has become widely recognized throughout 
the industry that the productivity of its research and development 
expenditures has been declining; that is, the number of new drugs being 
produced has generally declined while research and development expenses 
have been steadily increasing. Similarly, FDA and analysts reported 
that pharmaceutical research and development investments were not 
producing the expected results and that innovation in the 
pharmaceutical industry had become stagnant.[Footnote 2] In addition, 
FDA reported that the industry was predominantly submitting NDAs for 
variations of existing drugs, rather than for new and innovative drugs, 
such as new molecular entities (NMEs)--potentially innovative drugs 
containing active chemical substances that have never been approved for 
marketing in the United States in any form. In response to the 
declining productivity of drug development, FDA launched two separate 
initiatives--one in 2003 and another in 2004--to help facilitate drug 
development.[Footnote 3] In its 2004 initiative, it specifically cited 
an urgent need to improve the drug development process and to enhance 
collaboration among the government, industry, and academia. 

You raised questions regarding the numbers of new drugs being produced, 
and in particular, those drugs representing important therapeutic 
advances in effectively treating disease--such as NMEs. This report 
provides (1) data regarding trends in the pharmaceutical industry's 
reported research and development expenses as well as trends in the 
number of NDAs and NDAs for NMEs submitted to, and approved by, FDA; 
and (2) experts' views on factors accounting for these trends, and 
their suggestions for expediting the drug development process and 
increasing the productivity of research and development efforts. 

To determine trends in the pharmaceutical industry's reported research 
and development expenditures, we obtained information from the 
Pharmaceutical Research and Manufacturers of America (PhRMA)[Footnote 
4] for the period 1993 through 2004, and adjusted it for inflation to 
2004 dollars.[Footnote 5] We did not independently verify these 
amounts; however, many researchers have cited these data as the best 
available information. To identify trends in the number of submissions 
and approvals of NDAs, we obtained and analyzed data from FDA on all 
1,264 NDAs submitted to the agency for review from January 1, 1993, 
through December 31, 2004. The information we reviewed on these 1,264 
NDAs included their status--whether the applications had been approved, 
withdrawn, or were still under FDA's review. In addition, we obtained 
FDA's initial assessment of the NDAs' review priority, whether the NDAs 
were for NMEs, specific dates documenting when an NDA was submitted, 
and all of FDA's decisions regarding the applications. We also 
discussed the results of our data analyses with FDA officials to obtain 
their perspective on drug development trends. 

To determine factors underlying new drug development trends, we 
interviewed experts from the pharmaceutical industry, academia, and a 
public interest group who possess knowledge of issues that have had an 
impact on drug development. We also interviewed some pharmaceutical 
industry analysts who had previously published reports on drug 
development issues. In addition, we organized a panel of experts--with 
assistance from the National Academy of Sciences (NAS)--that included 
experts from academia, the pharmaceutical industry, and patient 
advocates. We held this panel in order to provide a forum where widely 
recognized experts could collectively discuss drug development issues. 
The panel was not designed to build consensus on any of the issues 
discussed. The panelists provided their individual views, which do not 
necessarily reflect those of the organizations with which they were 
affiliated or the NAS. We asked these experts to identify factors 
affecting the development of new drugs, and in particular, innovative 
drugs such as NMEs. As part of the panel discussion, we asked them to 
identify incentives or actions that could expedite drug development and 
enhance the development of drugs that offer therapeutic advances in 
effectively treating diseases. Further, we reviewed and analyzed 
previously published reports and articles issued by pharmaceutical 
industry analysts, academic researchers, and the federal government. We 
reviewed these reports and articles to identify factors influencing 
drug development, and suggestions for expediting this process. Detailed 
information on our methodology is in appendix I and a list of the 
panelists is in appendix II. We conducted our work from July 2005 
through October 2006 in accordance with generally accepted government 
auditing standards. 

Results in Brief: 

Although the pharmaceutical industry has reported substantial increases 
in annual research and development costs, the number of NDAs submitted 
to, and approved by, FDA has not been commensurate with these 
investments. From 1993 to 2004, the industry reported that annual 
research and development expenses steadily increased from nearly $16 
billion to nearly $40 billion in real terms--a 147 percent 
increase.[Footnote 6] In contrast, the number of NDAs submitted 
annually increased at a lower rate--38 percent over this period--and 
generally declined over the past several years. The number of NDAs 
submitted annually increased from 74 to 129, or by 74 percent, between 
1993 and 1999, and generally declined after 1999. In 2004, sponsors 
submitted 102 applications to FDA--a 21 percent decrease from the 1999 
level. Similarly, the number of NDAs submitted to FDA for NMEs 
increased by only 7 percent over this period, and generally declined 
since 1995. From 1993 through 1995, the number of NDAs submitted for 
NMEs increased, but declined by 40 percent between 1995 and 2004. The 
percentage of NDAs submitted that were for NMEs also generally declined 
after 1995. These submission trends indicate that the productivity of 
research and development investments has declined. Regarding approval 
trends, FDA eventually approved most NDAs--961 or 76 percent overall-- 
and the percentage approved each year has remained relatively constant. 
However, the overall number of NDAs--and NMEs in particular--approved 
annually has generally been declining since 1996, which corresponds 
with the decline in submissions. 

Results from the discussion among panel members, our interviews with 
drug development experts and analysts, and our review of academic and 
industry reports identified several factors affecting the types of 
drugs being developed, and the length, costs, and failure rates of drug 
development. These factors include limitations on the scientific 
understanding of how to translate chemical and biological discoveries 
into safe and effective drugs; business decisions by the pharmaceutical 
industry that influence the types of drugs developed; uncertainty 
regarding regulatory standards for determining whether a drug should be 
approved as safe and effective; and certain intellectual property 
protections that can discourage innovation. Together, these factors 
have been cited as affecting the cost and length of the drug 
development process, as well as the types of drugs being produced. 
Faced with these issues, some of the panelists, other experts we 
contacted, and the literature we reviewed, suggested ways to expedite 
drug development and find more innovative drugs. These include 
generating greater numbers of scientists who possess the skills needed 
to translate drug discoveries into effective new medicines; 
restructuring regulation of the drug review process to allow for 
conditional approval of drugs for therapeutic areas that currently lack 
effective treatments based on shorter clinical trials using fewer 
numbers of patients; and altering the length of patent terms to 
encourage innovation. Some of the experts have cautioned that adequate 
measures to ensure safety need to be implemented along with any changes 
to expedite the regulatory review process. 

In its comments on a draft of this report, HHS provided clarifications, 
which we incorporated as appropriate. 

Background: 

FDA is responsible for helping to ensure the safety and effectiveness 
of drugs marketed in the United States. It oversees the drug 
development process, reviews drug sponsors' applications for the 
approval of new drugs, and monitors the safety and efficacy of drugs 
once they are available for sale. As part of its responsibilities, FDA 
assists drug sponsors in designing clinical trials to test drugs on 
humans, reviews proposals for conducting such trials, and approves 
drugs for sale in the United States based on its determination that a 
drug's clinical benefits outweigh its potential health risks, and is 
safe and effective. Prior to a manufacturer's marketing of a drug, FDA 
reviews drug labels and accompanying materials to ensure they are 
consistent with applicable laws and regulations. Among other things, 
labels must include information on the drug's usage, for example, the 
medical conditions and patient populations for which it has been tested 
and approved as safe and effective. 

The Drug Discovery, Development, and Review Process: 

The process of bringing a new drug to the market consists of four main 
stages--drug discovery, preclinical testing, clinical trials which 
involve testing on volunteers, and FDA review. During these stages, 
scientists from the government, academia, and the private sector 
conduct extensive research and testing to identify safe and effective 
medicines. The entire drug discovery, development, and review process 
takes, on average, 15 years to complete. 

During the first stage--commonly referred to as drug discovery-- 
numerous researchers from pharmaceutical companies, academia, and 
government search for and identify promising chemical entities, or 
compounds, capable of curing or treating diseases. During the second 
stage--preclinical testing--these compounds are tested in laboratories 
and in animals to predict whether a drug is likely to be safe and 
effective on humans. Most compounds fail during these first two stages; 
according to PhRMA, only 5 in every 10,000 compounds, on average, 
successfully completes these two stages. In general, these two stages 
typically take a total of 6½ years to successfully complete for a 
particular compound. 

If the compound is found to be promising, a drug sponsor may decide to 
test it as a new drug on humans, and proceeds to the third stage-- 
clinical trials. Before doing so, a sponsor must submit an 
investigational new drug application (IND)[Footnote 7] that summarizes 
the data that have been collected on the compound and outlines plans 
for the clinical trials.[Footnote 8] Generally, clinical trials may 
begin 30 days after FDA receives the IND, unless FDA orders a delay. 
FDA does not issue a formal approval to the sponsor regarding an IND 
submission, but it can prohibit the start of a clinical trial if, for 
example, it determines that human volunteers would be exposed to an 
unreasonable and significant risk of illness or injury. As described 
below, the clinical trial stage consists of three phases, known as 
Phase 1, 2, and 3 clinical trials. 

In Phase 1 clinical trials, sponsors typically conduct safety studies 
on about 20 to 100 healthy volunteers. Potential side effects are 
identified and various dosage levels are determined. In Phase 2 
clinical trials, the drug is typically tested on approximately 100 to 
500 volunteers who have a particular disease to determine the drug's 
effectiveness. In Phase 3 clinical trials, the drug is typically tested 
on about 1,000 to 5,000 volunteers, to determine the drug's safety and 
effectiveness. According to PhRMA, on average, one out of every five 
drugs successfully completes all three clinical testing phases--that 
is, is found safe and effective by the drug sponsor and submitted as an 
NDA to FDA for review and approval. On average, the three phases of the 
clinical trial stage take a total of 7 years to successfully complete. 

The fourth and final stage is the FDA review stage, which covers FDA's 
review and final approval of NDAs. The review process begins when a 
sponsor submits an NDA to FDA. The NDA contains scientific and clinical 
data submitted by the sponsor intended to demonstrate that the drug is 
safe and effective for its proposed use. FDA evaluates data contained 
in the NDA to determine whether the drug meets these standards and if 
it should be approved.[Footnote 9] For those NDAs that are approved, it 
typically takes about 1½ years to complete the review process and 
obtain FDA's approval. 

Figure 1 shows the amount of time, on average, for a successful new 
drug to move through and complete the four stages. It also illustrates 
that for every 10,000 compounds initially identified, only one, on 
average, will be found safe and effective, and be approved by FDA. 

Figure 1: Figure 1: The Drug Discovery, Development, and Review 
Process: 

[See PDF for image] 

Source: Pharmaceutical Research and Manufacturers of America. 

[End of figure] 

Upon receipt of an NDA, FDA will classify it in two ways--by its 
chemical type and its therapeutic potential. First, an NDA is 
classified into chemical types, one of which is an NME.[Footnote 10] 
Because NMEs contain active chemical substances never before approved 
for marketing in the United States, industry analysts and FDA generally 
consider them innovative. The other six classifications consist of non- 
NMEs, which are typically considered less innovative because they 
represent modifications to drugs already on the market. In most cases, 
the sponsor submitting an NDA for a non-NME has altered the original 
medicine to produce a drug with different features, such as a new 
dosage form or route of administration. Second, FDA classifies an NDA 
by its therapeutic potential. In doing so, FDA compares the NDA to 
existing products already on the market. Those that appear to have 
relatively significant therapeutic benefits in the treatment, 
diagnosis, or prevention of a disease are classified as 
priority.[Footnote 11] Those with little or no additional therapeutic 
benefits compared to existing products are classified by FDA as 
standard. As figure 2 shows, an NDA can be classified in one of four 
ways--priority NME, priority non-NME, standard NME, or standard non- 
NME. 

Figure 2: Figure 2: FDA Classification of NDAs by Chemical Type and 
Therapeutic Potential: 

[See PDF for image] 

Source: GAO. 

[End of figure] 

In response to concerns that FDA was taking too long to review and 
approve NDAs, the Prescription Drug User Fee Act (PDUFA)[Footnote 12] 
was enacted in 1992. It provided FDA with additional resources in the 
form of user fees from the pharmaceutical and biotechnology industries 
to speed up the process of reviewing applications for new drugs and 
biological products, and established performance goals for FDA, 
including completing its review of a certain percentage of applications 
within certain time frames.[Footnote 13] PDUFA authorized FDA to 
collect these fees to supplement its annual appropriation for salaries 
and expenses, and use the additional funds to review applications more 
quickly.[Footnote 14] PDUFA was amended and reauthorized in 1997 and 
2002 for an additional 5 years and established new performance goals 
for various aspects of the drug review process. For example, current 
goals state that FDA should complete its initial review and act on 90 
percent of all priority NDAs within 6 months and 90 percent of all 
standard NDAs within 10 months. FDA uses these and other review time 
goals to assess its review timeliness, and issues an annual report on 
its performance to the President and Congress.[Footnote 15] 

The review process may span several review cycles. The first cycle 
begins when the NDA is submitted to and filed by FDA, indicating that 
the application is sufficiently complete to permit a substantive 
review. The first cycle ends when FDA has completed its review and 
responds by issuing an action letter to the sponsor. This could mean 
that FDA approved the application; told the sponsor it was approvable, 
but that more information was needed; or told the sponsor that the NDA 
contained significant weaknesses and was not approvable. If the 
application is approved in the first cycle, the total approval time is 
the length of that cycle. For those NDAs not approved during the first 
review--both approvable and not approvable--the second cycle begins 
when the sponsor files an amendment and resubmits the application and 
it is filed by FDA. The resubmission often contains additional studies, 
analyses, data, or clarifying information to address concerns raised by 
FDA in the previous review. As with the first cycle, this cycle ends 
when FDA has completed its review and issues an action letter to the 
sponsor. If the review process takes two or more cycles, the total 
approval time includes the time spent during the review cycles, plus 
the additional time the sponsor uses to address the issues raised by 
FDA. 

FDA Response to Concerns Over the Number of Drugs Developed: 

Over the past several years, numerous industry analysts and FDA noted a 
decline in the submission of applications for NDAs overall, and for 
innovative drugs, such as NMEs.[Footnote 16] In light of this, in 
January 2003, FDA launched a broad initiative to improve the 
development and availability of innovative medical products, including 
new drugs.[Footnote 17]As part of this initiative, FDA sought to 
reduce: (1) the number of drugs requiring more than one review cycle, 
(2) overall approval times, and (3) development costs. To help 
accomplish this, FDA sought to improve the development and review 
process by educating drug sponsors on the type and extent of scientific 
data that must be present in the NDA's initial submission. Noting the 
decline in the number of NDAs, in 2004 FDA proposed a second, more 
targeted, initiative--known as the critical path initiative--to form a 
collaborative effort between government, industry, and 
academia.[Footnote 18] In doing so, FDA cited an urgent need for a new 
product development "tool kit" to enable researchers to more 
effectively translate basic research discoveries into safe and 
effective products. Such tools include better techniques of identifying 
safety problems as early as possible and better methods for 
demonstrating medical effectiveness; tools, which according to FDA, 
could help reduce the failure rates of drug development and increase 
the number of NDA submissions. 

Drug Development Trends Are Not Commensurate with Research and 
Development Expenditures: 

Overall, our analyses of drug development data revealed that increases 
in research and development expenditures from 1993 through 2004 have 
not led to a commensurate increase in NDAs submitted to FDA, including 
those classified as NMEs. Although the pharmaceutical industry reported 
a 147 percent real increase in annual research and development 
expenditures from 1993 through 2004, and an increasing number of INDs 
are being submitted to FDA, the number of new drugs developed has not 
grown in a similar manner. Compared to industry-reported research and 
development expenditures, the number of NDAs and NDAs for NMEs 
submitted to FDA over the period increased at a lower rate--by 38 
percent and 7 percent respectively--which indicates that the 
productivity of the research and development investments has been 
declining. Furthermore, the majority of NDAs submitted to FDA were for 
non-NMEs, and thus represented modifications to existing drugs rather 
than newer and potentially more innovative drugs. FDA has consistently 
approved most of the NDAs submitted, with approval rates nearing 80 
percent overall, and has been approving applications much more quickly 
in recent years. However, the actual numbers of drugs approved annually 
has been declining, reflecting the trends in NDA submissions. 

The Productivity Associated with Research and Development Expenditures 
Has Recently Declined: 

According to PhRMA and industry analysts, research and development 
expenditures are key to the development of new and innovative medical 
products, including pharmaceuticals. During the drug discovery and 
preclinical stages, research and development expenditures fund efforts 
to identify new compounds that could ultimately become INDs. Research 
and development expenditures during the clinical trial phases fund the 
studies needed to prove a drug is safe and effective, leading to a 
potential NDA submission. Our review of annual research and development 
expense data reported by PhRMA and IND submission data reported by FDA 
indicate that there have been substantial and consistent increases in 
these expenses over the past decade, and that the number of INDs 
submitted to FDA has been increasing. However, we found that these 
investments have not led to a commensurate increase in the number of 
NDAs and NMEs, and thus, the productivity of these investments has 
declined. 

Figure 3, which shows the number of INDs that sponsors submitted to FDA 
from 1986 through 2005, indicates that there have been fluctuations in 
the number of INDs submitted each year.[Footnote 19] However, in 
general, sponsors have been submitting an increasing number of INDs 
since 1986. Figure 3 also shows a 45 percent increase in IND 
submissions over the last 2 years. 

Figure 3: Figure 3: IND Submissions, 1986-2005: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

Note: The data in this figure are for commercial INDs. 

[End of figure] 

Despite the trends of increasing IND submissions and steady increases 
in research and development expenses, we found that the number of NDAs 
submitted to FDA has generally been declining over the past several 
years. Figure 4 shows the annual research and development expenses 
reported by PhRMA for 1993 through 2004 (adjusted for inflation to 2004 
dollars), and the total number of NDAs (including those for NMEs) and 
NDAs for NMEs submitted to FDA during the same period.[Footnote 20] As 
figure 4 shows, annual research and development expenses grew 
consistently over the period. In 1993, the inflation-adjusted expenses 
were nearly $15.7 billion, and grew to an estimated $38.8 billion in 
2004--a 147 percent real increase over the period.[Footnote 21] Our 
analysis also revealed that inflation-adjusted annual growth rates of 
the research and development expenses ranged from a low of just over 2 
percent from 2001 to 2002, to over 11 percent from 1999 to 2000. 

Figure 4: Figure 4: Research and Development Expenses (Constant 2004 
Dollars), Total NDA, and NDA for NME Submission Trends, 1993-2004: 

[See PDF for image] 

Source: GAO analysis of PhRMA and FDA data. 

[End of figure] 

In contrast to the steady and large increase in research and 
development expenditures, we found that the number of NDAs submitted 
annually increased at a lower rate--38 percent over this period--and 
has generally declined over the past several years. As figure 4 shows, 
there was initial growth followed by a general decline in submissions 
of all NDAs, including NDAs for NMEs, to FDA. For NDAs, figure 4 shows 
that the number submitted to FDA, in general, grew from 1993 through 
1999. In 1993, sponsors submitted 74 NDAs to FDA. In 1999 this number 
grew to 129--a 74 percent increase from 1993. After 1999, however, NDA 
submissions generally declined, and in 2004, sponsors submitted 102 
NDAs, which represented a 21 percent decrease from 1999 levels. Figure 
4 also shows that the number of NDAs submitted to FDA for NMEs 
increased slightly over this 12-year period--by 7 percent. In addition, 
Figure 4 shows that the number of NMEs submitted to FDA peaked in 1995, 
and, for the most part, then began to decline. Although sponsors 
submitted 50 NMEs in 1995, this number fell to 30 in 2004, which 
represented a 40 percent decline. It should be noted that submissions 
of NDAs for NMEs increased during the last 2 years of this time frame-
-rising from 23 in 2002, to 28 in 2003, and 30 in 2004. 

Because it may take several years from the time research and 
development investments are made until the time a sponsor submits an 
NDA to FDA for approval, expenses in any given year are generally not 
related to NDA submissions in that year. Additionally, given the 
uncertain nature of research and development efforts, it is unlikely 
that expenditures and NDA submissions would grow at the same rate. 
However, given a 147 percent increase in research and development 
expenditures over the 12-year period, many analysts and experts assumed 
that the trend in NDA submissions would also generally be one of 
consistent increases. The NDA submission trends, combined with IND 
submission trends, indicate that the industry faces challenges in 
successfully completing the clinical testing stage, leading up to the 
submission of an NDA. 

Most NDAs Were for Modifications to Existing Drugs: 

In addition to determining the overall trends in the number of NDAs and 
NMEs submitted to FDA, we used FDA chemical type and therapeutic 
potential classifications--NME, non-NME, priority, and standard--to 
make a general assessment of the level of innovation of the NDAs 
submitted. Any one NDA--regardless of whether it is for an NME or was 
granted priority status by FDA--may eventually turn out to be an 
innovative and uniquely therapeutic product. However, FDA and industry 
analysts use the chemical type and therapeutic potential 
classifications to make a general assessment of the innovative 
potential of NDAs at the time of submission. We used the four 
classifications as outlined in table 1 to rank the innovative potential 
of NDAs.[Footnote 22] 

Table 1: Ranking of Innovative Potential of NDAs Using Chemical Type 
and Therapeutic Potential Classifications: 

NDA submission type: Priority NME; 
Level of potential innovation: 1. 

NDA submission type: Standard NME; 
Level of potential innovation: 2. 

NDA submission type: Priority non-NME; 
Level of potential innovation: 3. 

NDA submission type: Standard non-NME; 
Level of potential innovation: 4. 

Source: GAO analysis of FDA chemical type and therapeutic potential 
classifications. 

Note: The ranking of 1 represents the highest innovative potential, and 
4, the lowest. 

[End of table] 

Based on how FDA classified the 1,264 NDAs submitted from 1993 through 
2004, we determined the proportion of NDAs submitted by each of the 
four classifications. As figure 5 shows, 68 percent of the NDAs were 
classified as non-NMEs--those representing modifications to existing 
drugs, while the remaining 32 percent of the NDAs submitted were NMEs. 
The figure also shows that 12 percent of NDA submissions were for drugs 
in the priority NME classification--those representing the highest 
potential level of innovation. 

Figure 5: Figure 5: Proportion of 1,264 NDAs Submitted by Innovation 
Potential, 1993-2004: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

[End of figure] 

Based on FDA's classification of the 1,264 NDAs, we determined the 
percentage submitted each year that were NMEs and priority NMEs. 
Regarding NMEs, figure 6 shows that during the period 1993 through 
2004, there was variation from year to year in the percentage of NDAs 
submitted that were NMEs. Figure 6 shows that this percentage ranged 
from a high of 43 in 1995 to a low of 24 in 2002. It also shows that 
although this percentage had generally declined since 1995, it 
increased from 2002 through 2004. 

Figure 6: Figure 6: Percent of NDAs Submitted that were NMEs, 1993- 
2004: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

[End of figure] 

Regarding priority NMEs, figure 7 shows that in general, the percentage 
of NDAs that were priority NMEs ranged from between 10 and 15 percent 
during the 12-year period. Figure 7 also shows that this percentage 
ranged from a high of 15 in 2003, to a low of 5 in 2001. Finally, it 
shows that after a steep reduction in 2001, this percentage increased 
the following 3 years to levels similar to those previously 
experienced. 

Figure 7: Figure 7: Percent of NDAs Submitted that were Priority NMEs, 
1993-2004: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

[End of figure] 

The results of our analyses indicate that the reported increases in 
research and development expenditures during the period have not led to 
a commensurate increase in the innovative potential of NDAs submitted 
to FDA. These findings are consistent with FDA's conclusions in its 
2003 and 2004 reports. In its January 2003 report on improving 
innovation in medical technology--including drugs--FDA found that data 
regarding application submissions showed a trend toward decreased 
numbers of applications for truly innovative products, including 
NMEs.[Footnote 23] The report also concluded that the trends were of 
concern to FDA because at the same time, it had seen a substantial 
increase in the number of applications for new products, including new 
drugs in areas where comparable products already existed--such as non- 
NME NDAs. Further, these same trends, which suggested stagnation in 
innovation, were noted as a basis for FDA's launch of the critical path 
initiative in 2004. 

FDA Approves Most NDA Submissions, and Approval Times Have Been 
Decreasing: 

We reviewed the status of all 1,264 NDAs submitted from January 1, 
1993, through December 31, 2004, to determine approval trends. Our 
review found that as of September 2005, FDA had approved 961, or 76 
percent of the NDAs submitted. Further, we found that FDA approval 
times have been decreasing and that approval times were consistently 
shorter for priority NDAs. We also found that most of the NDAs approved 
from 1993 through 2004 were for non-NMEs, or modifications to drugs 
already on the market. Finally, reflecting the declining number of NDA 
submissions, we found that the numbers of NDAs and NMEs approved each 
year have generally been declining. 

The status of the 1,264 NDAs as of September 2005, shown in figure 8, 
indicates that FDA had approved the majority of them, and the remaining 
were either still under FDA review or had been withdrawn by the 
sponsors. 

Figure 8: Figure 8: Status as of September 2005 for the 1,264 NDAs 
Submitted, 1993-2004: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

[End of figure] 

In addition to determining the overall approval rate over the period, 
we calculated approval rates for each year the NDAs were submitted. We 
found that approval rates were consistently above or near 80 percent 
for years 1993 through 2000. Approval rates for the later 4 years--and 
years 2003 and 2004 in particular--were lower because many of the NDAs 
submitted--34 of the 106 submitted in 2003 and 51 of the 102 submitted 
in 2004--were still under FDA review at the time of our 
analyses.[Footnote 24] 

We also calculated the length of time it took FDA to approve each of 
the 961 NDAs, and determined the trends in average approval times based 
on the year the NDAs were submitted. Our analysis showed that the 
average time it has taken FDA to approve NDAs submitted in recent years 
is generally lower than for those submitted in earlier years. For 
example, we found that it took FDA, on average, 669 days to approve 
NDAs submitted in 1993, but only 442 days to approve those submitted in 
2002--a 34 percent decrease.[Footnote 25] This decrease is due, in 
part, to the fact that FDA has been approving an increasing number of 
NDAs in one or two review cycles, which has helped cut overall approval 
times. 

Additionally, we found that approval times for priority NDAs were 
consistently lower than for standard NDAs. This was due, in part, to 
the fact that for those priority NDAs approved, FDA approved 63 percent 
of them in one review cycle, compared to 46 percent for the standard 
NDAs. Figure 9 shows the average approval times for priority and 
standard NDAs based on the year they were submitted, from 1993 to 2004. 
It should be noted that PDUFA was in effect during the period covered 
in figure 9. During that time FDA collected user fees and was subject 
to PDUFA performance goals. 

Figure 9: Figure 9: Average Approval Times as of September 2005 for 961 
Priority and Standard NDAs Submitted and Approved, 1993-2004: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

Note: NDA approval times include the time taken by FDA to review the 
application as well as time needed by the sponsor to address FDA's 
concerns. In addition, 85 of the 208 the applications submitted in 2003 
and 2004 were still under review at the time of our analyses, and thus 
average approval times for these years may increase if they are 
eventually approved. 

[End of figure] 

Previous studies have indicated that implementation of PDUFA's user 
fees and performance review goals have been a contributing factor to 
the quicker review times. For example, in 2002, we reported that fees 
collected under PDUFA had provided FDA with additional resources that 
have helped the agency expedite the approval of new drugs by reducing 
review times.[Footnote 26] In addition, an October 2000 study by the 
Tufts Center for the Study of Drug Development concluded that user fees 
contributed to a 51 percent drop in average approval times from 1993 
through 1998.[Footnote 27] 

To categorize the innovative potential of the drugs submitted and 
approved during the period, we applied the same four-level ranking 
scale discussed earlier to the 961 NDAs that FDA approved. Based on our 
analysis, we found that, similar to the submission trends, most of the 
NDAs approved were for non-NMEs. Figure 10 shows the proportion of the 
NDAs categorized by innovative potential. 

Figure 10: Figure 10: Proportion of 961 NDAs Submitted and Approved by 
Innovation Potential: 

[See PDF for image] 

Source: GAO analysis of FDA data. 

[End of figure] 

We also obtained historical data on the numbers of NDAs overall, as 
well as NDAs for NMEs that FDA has approved regardless of when they 
were submitted.[Footnote 28] In doing so, we reviewed FDA's published 
data on its annual approvals of NDAs, including NDAs for NMEs for the 
years 1993 through 2005.[Footnote 29] Figure 11, which is based on 
these data, shows that FDA approved an increasing number of NDAs and 
NDAs for NMEs from 1993 through 1996. After that time, however, 
reflecting the declining number of NDA submissions, annual approvals 
declined, and returned to levels not seen since the early 1990s. Also, 
there was a spike in the number of approvals in 2004, but approvals 
were lower once again in 2005. 

Figure 11: Figure 11: Total NDA and NDA for NME Approvals, 1993-2005: 

[See PDF for image] 

Source: GAO analysis of FDA data, 

[End of figure] 

Experts Identified Factors Contributing to Declining Productivity in 
Drug Development and Offered Suggestions for Improvement: 

According to experts, a variety of factors have contributed to the 
declining productivity of pharmaceutical research and development 
efforts by making it more difficult for the industry to successfully 
complete clinical testing and submit NDAs for approval. These factors 
include limitations on the scientific understanding of how to translate 
chemical and biological discoveries into safe and effective drugs, 
business decisions by the pharmaceutical industry, uncertainty 
regarding regulatory standards for determining whether a drug should be 
approved, and intellectual property issues, such as the length of 
patent terms. According to experts, these factors have impacted the 
length, costs, and failure rates of drug development, as well as the 
innovative potential of NDAs being submitted to FDA. Although experts 
agreed that declining productivity may be a cyclical occurrence that 
will ultimately be reversed, they also acknowledged that they need to 
address the recent increase of clinical trial failure rates--from 82 
percent during the period 1996 through 1999, to 91 percent during the 
period 2000 through 2003. As a result, they have proposed suggestions 
to expedite drug development and improve the overall productivity of 
research and development efforts. 

Lack of Scientific Understanding in Treating Diseases Contributes to 
Increased Failure Rates and Increased Research and Development 
Expenditures: 

We found a general consensus that difficulties in effectively 
translating basic research discoveries into new and effective medicines 
have contributed to increased failure rates during clinical testing. In 
turn, this has led to increased costs of drug development. Difficulties 
in understanding the science of disease have historically challenged 
researchers. However, according to experts, these difficulties have 
been growing over the past several years as the volume of drugs in 
clinical trials and the complexity of the diseases to be addressed have 
increased. As a result, the inability of drug sponsors to consistently 
predict the efficacy of compounds, including those for complex 
diseases, has resulted in an increasing number of clinical failures and 
overall development costs. In addition, the inability of drug sponsors 
to effectively utilize new technologies and a shortage of highly 
trained researchers who possess the ability to effectively translate 
basic discoveries into new drugs, were seen as factors that further 
contribute to the increased clinical failures and costs. 

During the panelists' discussion, it was generally agreed that the 
inability to effectively predict which compounds will be successful 
when tested in humans, combined with the greater numbers of compounds 
in clinical testing, have contributed to the increased number of drugs 
failing clinical testing and rising expenditures. Panelists commented 
that compounds which were thought to be effective treatments during 
preclinical testing in animals can ultimately fail when tested in 
humans because available animal models used to estimate a compound's 
effectiveness have limited ability to predict whether they will be 
effective in treating humans.[Footnote 30] This issue was also 
highlighted in a joint report issued by the Association of American 
Medical Colleges (AAMC) and FDA, which found that although animal 
models can be useful by providing biological insights, there is still a 
lack of understanding when it comes to extrapolating results from 
animal models to human studies.[Footnote 31] 

According to industry analysts, the pharmaceutical industry's 
increasing focus on developing drugs for complex and chronic diseases 
such as cancer has also contributed to higher failure rates, slower 
drug development, and increased costs. Because many of these diseases 
have not been fully studied, knowledge of how drugs impact relevant 
cells remains incomplete. For example, scientists have rarely been able 
to develop cancer therapies that exclusively eliminate cancer cells 
without also destroying healthy tissues. As a result, many cancer drugs 
have failed in clinical testing because of adverse side effects. 
Analysts have noted that in order to document the safety and efficacy 
of drugs used to treat complex and chronic diseases, longer studies 
with larger patient populations are required, which increases both 
development time and costs. Similarly, analysts reported in 2003 that 
therapies for complex and chronic conditions are generally more costly 
to test, as they typically require more complex patient care and longer 
monitoring periods.[Footnote 32] 

Over the past decade, new technologies including genomics and high- 
throughput screening have provided tools for researchers to discover 
and test compounds.[Footnote 33] According to industry analysts, the 
use of these technologies has led to increasing expenses without a 
commensurate increase in the number of drugs developed. These analysts 
have found that although companies have invested substantial resources 
in acquiring technologies that have generated vast quantities of newly 
discovered biological data, company researchers are still learning 
whether the data will lead to potentially valid drug candidates, 
resulting in compounds and drugs that have failed in either preclinical 
or early clinical testing. While the panelists generally agreed that 
the productivity of the pharmaceutical industry is currently declining, 
they stressed that this trend may be part of a cycle that will reverse 
itself, as researchers improve their ability to exploit these 
technologies. 

Furthermore, a shortage of physician-scientists, also known as 
translational researchers--who possess both medical and research 
degrees and thus the expertise needed to translate discovery-stage 
research into safe and effective drugs--was seen by panelists and other 
experts as a fundamental barrier to increasing the productivity of drug 
development. During the panel discussion, it was generally agreed that 
a shortage of translational researchers was a key factor contributing 
to the declining productivity of pharmaceutical research and 
development efforts, particularly with the increasing use of new 
technologies and the shift in research focus to more complex diseases. 
In addition, analysts have reported on this decline, and cited research 
which found that the number of physician-scientists declined by 22 
percent from 1983 to 1998.[Footnote 34] Experts attribute this shortage 
to a variety of factors, including lengthy training and relatively 
lower compensation for physicians who are scientists, compared to those 
in clinical practice. In addition, researchers, including those in 
academia, have noted that academic institutions have not taken the 
initiative to provide financial incentives, such as scholarships, for 
medical students to pursue these research interests. 

The Business Environment Drives Drug Development Decisions: 

Experts generally agreed that business considerations greatly influence 
the industry's priorities of what drugs to pursue. The conflicting 
pressures of avoiding risk and producing a high return on investment, 
in addition to the recent mergers of pharmaceutical companies, have 
shaped business decisions and affected productivity. 

Over the past 10 years, the trend in the pharmaceutical industry has 
been to focus on developing drugs that produce a high return on 
investment, which has reduced the numbers and types of drugs produced. 
This strategy has led pharmaceutical companies to pursue development of 
blockbuster drugs, which are usually for large patient populations and 
have the potential to reach $1 billion in annual sales. Blockbuster 
drugs may be developed to the exclusion of other drugs for more limited 
populations that generate much less revenue. Drug development experts 
and several panelists reported that companies frequently choose to stop 
developing drugs that do not offer the same revenue-generating 
potential as blockbuster drugs, even though they could be highly 
innovative and offer therapeutic advances. According to an industry 
consultant we contacted, pharmaceutical companies have annual sales 
thresholds in place which play a key role in determining which drugs to 
continue developing.[Footnote 35] The emphasis on developing 
blockbuster drugs has been highlighted by numerous industry analysts, 
who have noted that the number of blockbuster drugs being sold has more 
than doubled over the past several years. This strategy can also 
diminish the amount of resources available to develop therapies to 
treat more limited patient populations and less visible 
diseases.[Footnote 36] Due to increased competition among companies, 
the blockbuster strategy has also been cited as a factor leading to 
increased costs from late-stage development failures. According to 
researchers we interviewed from the Tufts Center for the Study of Drug 
Development, although companies have pursued drugs that they believed 
had huge market potential, they later discovered that the potential for 
substantial revenue no longer existed for some of these drugs because 
competitors had already begun marketing similar drugs. Tufts 
researchers stated that such companies subsequently discontinued 
production of what they thought would be blockbuster drugs, and that 
often times these decisions were made late in Phase 3--the most complex 
and costly phase--and thus companies discontinued development after 
incurring substantial costs. 

Industry analysts have also reported that with increased development 
costs and complexity, and with more competition, companies prefer to 
produce drugs that require little risk taking but still offer the 
potential for high revenues. This strategy has created an emphasis on 
producing "me too" drugs--drugs which have a very similar chemical 
formulation to drugs already on the market. These drugs are less risky 
to develop because the safety and efficacy of the drugs on which they 
are based have already been studied. According to one panelist, an 
industry representative, because the length, complexity, and expense of 
developing a single drug have all increased dramatically over the last 
10 to 15 years, companies must choose fewer drugs to develop. As a 
result, they will often follow a business model that involves choosing 
drugs that are easy to develop, with a large market that will produce a 
large return on investment. 

Some experts and analysts who are critical of the pharmaceutical 
industry often state that the emphasis on "me too" drugs reduces 
innovation because such drugs do not offer any significant therapeutic 
benefits over products already being sold.[Footnote 37] For example, 
they state that companies have produced different drugs all designed to 
combat depression or reduce cholesterol, and that such "me too" drugs 
have similar therapeutic benefits. As a result, these critics assert 
that this strategy diverts resources from developing drugs that offer 
greater innovative potential. However, industry analysts report that 
"me too" drugs benefit consumers by offering alternative and safer 
therapies. For example, they indicate that the side effects and 
efficacy of these drugs can vary from person to person, which gives 
physicians more options in treating their patients. In addition, 
analysts report that "me too" drugs increase competition, which can 
lower the price of drugs in the market. 

Another major business strategy that has affected the success of drug 
development since the early 1990s is mergers and acquisitions in the 
pharmaceutical industry.[Footnote 38] According to industry analysts, 
the industry pursued mergers and acquisitions because it anticipated it 
would increase the productivity of research and development. Instead, 
they noted that with the rise in research and development costs, the 
newly formed company often reviews its combined inventories of 
potential products and selects only the most promising compounds for 
further development. For example, after consolidating their research 
efforts, the company may choose to discontinue one of the individual 
company's previous research areas because the projected financial 
benefits of the product lines fail to meet the new company's revenue 
expectations. In addition, analysts have found that mergers and 
acquisitions may also result in additional pressure to develop a 
blockbuster drug because investors expect the combined company to 
generate a substantial growth in revenue. According to a summary of a 
winter 2002-2003 Tufts survey[Footnote 39] of 35 clinical research 
organizations, merger and acquisition activity was cited as a large 
barrier to drug development.[Footnote 40] Due to mergers and 
acquisitions, nearly 50 percent of these organizations reported that 
drug development projects were cancelled during the 2 years prior to 
the survey, and that 90 percent experienced project delays. 

Factors in the Operating Environment Affect Drug Development Outcomes: 

Based on the results of discussion among panel members, our interviews 
with drug development experts, and our review of prior studies, we 
identified several other factors that affect the numbers, types, and 
costs of drugs being developed. These factors affect the operating 
environment in which drug sponsors make their decisions, and play a 
role in shaping development priorities. They include sponsors' 
uncertainty over how they are to implement requirements for the safety 
and efficacy of new drugs, and the impact of intellectual property 
protections on pharmaceutical innovation. 

Regulatory Uncertainty Can Hamper Drug Development: 

We found that uncertainties regarding regulatory requirements 
concerning both drug safety and effectiveness can impact the success of 
drug development efforts. During the panel discussion, there was 
general agreement that the lack of precise FDA regulatory standards 
that outline what constitutes a safe and effective drug is a factor 
when making drug development decisions--weighing the safety of drugs 
against their potential therapeutic benefits. Panelists generally 
agreed that because there are no precise standards for making these 
decisions, sponsors and FDA must address them on a case-by-case basis. 
As a result, it was indicated that this uncertainty may lead a drug 
sponsor to abandon a drug rather than risk significant development 
expenditures. Panelists also indicated that this uncertainty creates 
risk-averse behavior that can reduce the prospects for innovative 
therapies. During the panel discussion and interviews, FDA officials 
acknowledged that the regulatory standards are not precise and that it 
needs to have flexibility to address safety and efficacy issues as they 
arise. For example, FDA officials stated that they may discover a new 
drug-to-drug interaction that could affect the safety risks of an NDA 
under review, and in such a case, they would utilize the new 
information to address previously unknown safety issues. 

We also identified a perception held by some drug development experts 
and industry analysts that FDA, in response to several events involving 
drug safety, has increased its review requirements during the drug 
development process. Some analysts believe that these increased review 
requirements have contributed to the increased time and costs of drug 
development by requiring more complex and costly studies. Some analysts 
have reported that safety concerns during the 1990s--which led FDA to 
request that manufacturers withdraw pharmaceuticals including 
fenfluramine and dexfenfluramine (known as Fen-Phen) in 1997, Propulsid 
and Rezulin in 2000, and Baycol in 2001--impacted FDA's review 
requirements.[Footnote 41] For example, a 2004 report completed for the 
European Commission--the executive body of the European Union--found 
that the withdrawals of these pharmaceuticals from the market affected 
FDA's implementation of its regulatory standards.[Footnote 42] 
According to this study, FDA began to demand more complex clinical 
trials that called for more testing on: (1) how drugs interact with 
each other, (2) the effect of drugs on liver toxicity, and (3) the 
relationship of drugs to cardiac risk. In addition, according to 
several drug development experts and some industry analysts, FDA has 
been requiring more lengthy and complex clinical trials, which call for 
more patients and increased costs. For example, according to one 
analysis, the average number of patients participating in clinical 
trials per NDA increased by 19 percent during the period 1995 to 2001, 
as compared to the period 1990 to 1994, due, in part, to increasing 
federal regulations.[Footnote 43] In its comments on a draft of this 
report, HHS acknowledged that FDA may be increasing data requirements 
in some instances. However, it stressed that in many cases, the 
increase in the amount of data submitted results from a sponsor's 
decision to provide support for new claims or to better position its 
product relative to existing products. 

Our review of studies and interviews with several experts revealed that 
there is a lack of consensus among FDA, industry, and academia as to 
what can constitute a valid measurement for proving the effectiveness 
of drugs for many diseases. As a result, these sources indicate that 
drug development can be more complex, lengthy, and costly than 
necessary, because drug sponsors are unsure how to demonstrate a drug's 
effectiveness. Drug sponsors rely on end points--or objective 
measurements--to evaluate effectiveness. Clinical end points 
demonstrate the effectiveness of a drug on a human, such as a 
medication that can be proven to prevent strokes. However, it can be 
easier to prove a drug's efficacy by using valid biomarkers as 
surrogate end points (e.g., showing a medicine is effective in reducing 
blood pressure instead of proving it will prevent strokes).[Footnote 
44] FDA has approved many drugs to treat the HIV/AIDS virus using 
surrogate end points. However, due to the uncertainty among FDA, 
industry, and academia over when it is appropriate to use surrogate end 
points, expanding their use has been difficult, and has been recognized 
by FDA as one issue that needs to be addressed. For example, in its 
March 2004 paper outlining the critical path initiative, FDA concluded 
that adopting new biomarkers and surrogate end points for effectiveness 
standards can drive rapid clinical development, and that efforts are 
needed to develop them to help guide drug development.[Footnote 45] 
This issue was also extensively addressed in the joint report issued in 
2005 by FDA and the AAMC in response to FDA's critical path 
initiative.[Footnote 46] That report identified a need to clarify 
guidance governing the level of evidence required to support the use of 
biomarkers and surrogate end points. In March 2006, FDA published a 
report outlining six areas to help increase productivity in drug 
development.[Footnote 47] One of these areas included developing new 
biomarkers which, according to FDA, could increase the safety of new 
drugs, reduce the costs of clinical trials, and expedite drug 
development. According to FDA's senior manager for its critical path 
initiative, the agency is currently working with industry and academia 
to develop biomarkers and other tools to enhance the drug development 
process. 

Intellectual Property Protections Have Affected Drug Development: 

During our review, we found a wide variety of views among consumer 
advocates, drug development experts and analysts, and industry 
representatives regarding how the protection of intellectual property 
affects innovation in drug development. Intellectual property 
protections are designed to help encourage innovation by providing 
financial incentives to engage in research and development efforts. 

One form of intellectual property protection is a patent, which 
provides its owner with the right to exclude others from making, using, 
or selling an invention for 20 years.[Footnote 48] In the United 
States, the U.S. Patent and Trademark Office issues patents. Typically, 
companies that develop brand-name drugs obtain a patent on the active 
ingredient used in the drug. Patents are seen as playing a key role in 
drug development, because they allow pharmaceutical companies to charge 
prices that allow them to recover their investments made in discovering 
and developing a new drug and earn a profit. Drug manufacturers 
typically apply for patents for compounds while their medicinal 
properties are still being developed and evaluated. Therefore, the 
quicker companies are able to develop a new drug and receive market 
approval from FDA, the more time they have to sell their drugs without 
facing competition. The amount of patent protection remaining after 
receiving FDA market approval is known as the effective life of a 
patent. 

Through both their reports and our interviews with them, consumer 
advocates and some pharmaceutical industry analysts expressed concerns 
that certain intellectual property protections do not encourage 
innovation.[Footnote 49] First, they contended that companies can 
easily obtain new patents by making minor changes to existing products 
regardless of whether the drugs offer significant therapeutic advances. 
Second, they indicated that pharmaceutical companies may develop new 
uses for previously approved drugs that have no patent protection and 
receive an additional 3 years of "market exclusivity."[Footnote 50] 
According to these sources, these intellectual property protections 
enable companies to earn significant profits while reducing the 
incentive to develop more innovative drugs. These sources pointed to 
the relatively high percentage of non-NMEs, and standard NMEs in 
particular, that have been approved over the past decade as evidence 
that development efforts have focused on making changes to existing 
drugs. Some analysts specifically highlighted the practice commonly 
known as producing line extensions--deriving new products from existing 
compounds by making small changes to existing products, such as 
changing a drug's dosage, or changing a drug from a tablet to a 
capsule. According to analysts, these changes are typically made to 
blockbuster drugs shortly before their patents expire. Some analysts 
also concluded that this practice redirects resources that otherwise 
could be applied to developing new and innovative drugs. 

In contrast, the pharmaceutical industry contended that due to the 
rising costs and complexity of developing new drugs, these intellectual 
property protections are crucial to maintaining drug development 
efforts.[Footnote 51] Drug sponsors and industry analysts also 
indicated that new drugs produced by modifying existing compounds are 
the result of incremental innovation, and such drugs can result in 
important therapies. For example, by changing a medicine to reduce its 
dosage schedule requirements, some industry analysts indicated that 
patients are more likely to comply with their prescription's 
instructions. Finally, some analysts assert that the revenues generated 
from incremental innovation are needed to fund the more risky ongoing 
research and development efforts, which can lead to new innovations. 

Drug Development Experts Offered Suggestions to Improve Productivity 
and Innovation: 

While panelists indicated that the productivity of drug development is 
currently in a downward cycle, and that the cycle would eventually 
reverse, they were uncertain when this would occur. Therefore, they 
recognized the importance of taking steps to develop and implement 
initiatives to increase the number, and innovative potential, of drugs 
being produced. To help accomplish this, the panelists and other 
experts--including representatives from the pharmaceutical industry, 
academia, public interest groups, and FDA--made a variety of 
suggestions to reduce the costs, increase the speed, and encourage 
innovation in drug development. While not every expert mentioned every 
one of the suggestions below, or ranked them in a particular order, we 
found that certain suggestions were highlighted in the panel's 
discussion, our interviews, and academic and industry reports as having 
the potential to improve the productivity of drug development. However, 
some of these experts also cautioned that any change that expedites the 
drug development process should be tempered with appropriate measures 
to ensure that safety is not compromised. These suggestions include: 

² Collaborative efforts among the government, industry, and academia 
to: 

- Design a system to collect and analyze data on why drugs fail during 
clinical testing. For example, a team of FDA and pharmaceutical 
representatives could review FDA and company databases to obtain 
examples of drug failures and then perform a systematic analysis of the 
causes of these failures. This effort would need to ensure protection 
of each company's proprietary information on specific drugs. Such an 
effort may provide new information to prevent multiple companies from 
making the same or similar mistakes and may increase efficiency in 
clinical trials. 

- Develop inventories of validated biomarkers and surrogate end points 
to use when testing the safety and efficacy of drugs in development. 
According to experts, to increase the utilization of validated 
surrogate end points, government, industry, and academia could also 
work together to clarify FDA's guidance and the level of scientific 
evidence needed to support the use of biomarkers and their validation 
as surrogate end points. 

- Identify diseases in great need of treatment, and implement an 
expedited regulatory process using conditional approval to decrease the 
time needed to develop drugs to treat these diseases. According to 
experts, a new expedited process would require less detailed study and 
information and allow for more limited clinical trials. Therefore, 
experts said that an expedited process would help lower the cost of 
creating drugs for these diseases, and serve as an incentive to 
increase drug development for such diseases. To help ensure safety, the 
drugs would have conditional approval--they would initially be 
distributed to certain populations whose usage of the drug can be 
studied and carefully monitored before wider distribution would be 
allowed.[Footnote 52] 

² Academia could place a greater emphasis on developing research 
scientists with knowledge of translational medicine by providing 
financial incentives, such as scholarships, for students to pursue this 
discipline. Private and public partnerships could also create these 
incentives to develop such scientists. One of the panelists suggested 
that academia, industry, and FDA formally develop a paper that 
describes the skills most needed by this new type of translational 
scientist and develop funding and training mechanisms that would 
specifically support these individuals. 

² The federal government could consider providing financial incentives 
or disincentives to affect the innovative potential of drugs produced 
by the industry. The government could achieve this by extending or 
reducing the period of patent protection associated with a drug based 
on its therapeutic value. One of the panelists suggested that a patent 
could be extended to 25 or 30 years for drugs considered innovative, or 
offering high therapeutic potential; while patents for drugs offering 
less innovative benefits could be only 10 years. 

Concluding Observations: 

Developing new drugs is complex, risky, and challenging. It is also 
important to the health and well-being of society, and can provide 
substantial financial rewards to companies. Recent trends reveal the 
number of drugs developed has not been commensurate with research and 
development investments by the pharmaceutical industry. While experts 
believe these trends are part of a cycle that can be reversed, there is 
no clear expectation of when the industry will become more productive-
-that is, producing greater numbers of new drugs, and more 
specifically, those representing significant therapeutic advances. The 
extent to which scientific, business, regulatory, and intellectual 
property issues related to drug development can be addressed will 
largely determine if and how quickly these trends can be reversed. 
Addressing this challenge will require effective collaboration between 
government, industry, and academic institutions. 

Agency Comments: 

HHS provided comments on a draft of this report. HHS's comments appear 
in appendix III. Among its general comments, HHS officials stated that 
our ranking of the innovative potential of NDAs based on FDA's chemical 
type and therapeutic potential classifications was misleading. 
Specifically, HHS disagreed with our premise that an NDA classified as 
a standard NME should be ranked as more innovative than one classified 
as a priority non-NME. It noted classification as an NME is not 
necessarily commensurate with innovation and gave an example of a 
priority non-NME that could offer more therapeutic potential than a 
standard NME. We noted in our draft, that any one NDA--regardless of 
whether it is for an NME or was granted priority status by FDA--may 
eventually prove to be an innovative and uniquely therapeutic product. 
However, our discussions with FDA officials and our review of prior 
studies--including those conducted by FDA--revealed a general consensus 
that the most important factor in assessing the innovative potential of 
an NDA at the time of submission was whether or not it was an NME. For 
example, FDA has highlighted the declining number of NDAs for NMEs as 
an indicator of the stagnation of innovation. In its 2003 initiative, 
it reported a decline in the number of submissions of NDAs for NMEs in 
both the priority and standard classifications and noted this was an 
indication of decreases in the submission of applications for truly 
innovative new products.[Footnote 53] 

HHS's general comments also noted that statutory changes may be needed 
to implement the experts' suggestion to expedite FDA's regulatory 
process by instituting a new system of conditional approval. Although 
we noted in the draft report that FDA has authority to issue 
conditional approvals for certain drugs to treat serious or life- 
threatening conditions under its current accelerated approval program, 
we agree that, depending on the specific parameters of any new system, 
statutory changes could be necessary. 

Further, HHS's general comments included additional clarifications. For 
example, HHS expressed concern that our explanation of why FDA could 
only provide data on NDAs through 2004 could be misleading and imply 
that FDA is not good at tracking its data. In response, we clarified 
the report to reflect that FDA provided data on NDAs through 2004 
specifically at our request, as this was the most recent year with a 
complete set of NDA submission data at the time our request was made. 
We also made other clarifications in response to HHS's general 
comments. In addition, HHS provided us with technical comments, which 
we incorporated throughout the report, as appropriate. 

As agreed with your offices, we plan no further distribution of this 
report until 30 days after its date. At that time, we will send copies 
of this report to the Secretary of HHS, the Acting Commissioner of FDA, 
appropriate congressional committees, and other interested parties. We 
will also make copies available to others upon request. In addition, 
the report will be available at no charge on the GAO Web site at  
[Hyperlink, http://www.gao.gov]. 

If you or your staff has any questions, please contact me at (312) 220- 
7600 or at aronovitzl@gao.gov. Contact points for our Offices of 
Congressional Relations and Public Affairs may be found on the last 
page of this report. GAO staff who made major contributions to this 
report are listed in appendix IV. 

Signed by: 

Leslie G. Aronovitz: 
Director, Health Care: 

[End of section] 

Appendix I: Scope and Methodology: 

To determine trends in the pharmaceutical industry's reported research 
and development expenditures, we obtained research and development 
expenditure information from the Pharmaceutical Research and 
Manufacturers of America (PhRMA). We obtained this information for the 
period 1993 through 2004, adjusted for inflation to 2004 dollars. We 
did not independently verify these expenditure data; however, many 
researchers have cited these data as the best available information, 
and they represented the best available information at the time of our 
study.[Footnote 54] 

To determine the trends in the number of submissions and approvals of 
NDAs, we requested that the Food and Drug Administration (FDA) provide 
information on all 1,264 new drug applications (NDA) submitted to FDA 
from January 1, 1993, through December 31, 2004.[Footnote 55] We chose 
this time period because it generally corresponds to changes FDA 
implemented to its process for reviewing NDAs. Specifically, in 1992, 
FDA implemented a new system for categorizing NDAs, using the priority 
and standard designations and in 1993, FDA implemented time-frame goals 
for reviewing NDAs. At the time we requested these data--July 2005-- 
information through 2004 was the most current year for which FDA could 
provide complete data. We also compared the trends in the numbers of 
NDAs and NDAs for new molecular entities (NME) submitted to FDA to the 
trends in the research and development expenditures over the same 12- 
year time frame. 

For each of the NDAs, we requested and obtained descriptive and status 
information--such as each NDA's unique number, its review designation 
(either priority or standard), whether it was for an NME, and all of 
the dates documenting when drug sponsors provided information to FDA 
and when FDA made decisions during the review and approval process. 
After receiving this information, we performed a series of data 
analyses to identify trends in the submission and approval of NDAs, and 
calculated approval time frames for the NDAs. In calculating approval 
time frames, we included both the time FDA spent reviewing the NDAs and 
any additional time needed by the sponsor to address any FDA review 
concerns. 

In addition to obtaining data on the 1,264 NDAs submitted from January 
1, 1993, through December 31, 2004, we obtained information from FDA on 
the number of NDAs and NDAs for NMEs the agency approved each year from 
1993 through 2005. We used this information to analyze NDA and NDA for 
NME approval trends, regardless of the years these NDAs were submitted. 
We also obtained information from FDA on the number of investigational 
new drug applications (IND) filed with the agency each year from 1986 
through 2005.[Footnote 56] We chose this time period for two reasons. 
First, because it takes 7 years, on average, to successfully complete 
clinical trials, trends emerging from INDs submitted in 1986 could be 
reflected in NDA submission trends beginning in 1993. Second, 2005 was 
the most recent year with complete data, and these IND data provided an 
indication of the productivity of research and development expenditures 
for the drug discovery and preclinical testing phases in more recent 
years. 

We performed various tests of data reliability, including obtaining 
information about the data collection and management system and its 
controls that FDA uses to ensure the data are reliable, and 
corroborating the data by comparing them to other published 
information. Based on our work, we believe the data we used were 
sufficiently reliable for the purpose of our report. 

To determine factors affecting new drug development, and to obtain 
experts' suggestions to expedite the process, we took several steps. 
First, we interviewed various experts from FDA, the pharmaceutical 
industry, health care organizations, a consumer group, and academia, 
who possess knowledge of issues that have had an impact on drug 
development. Specifically, we interviewed officials from FDA's Center 
for Drug Evaluation and Research and the Critical Path Institute--which 
was founded by FDA, the University of Arizona, and SRI International, 
an independent, nonprofit research institute. In addition, we spoke to 
experts from PhRMA and other pharmaceutical industry analysts, 
including an independent consultant to the pharmaceutical industry. We 
also interviewed representatives from the American Medical Association, 
the Association of Clinical Research Organizations, and the National 
Institute for Health Care Management. Finally, we interviewed officials 
from Public Citizen, a consumer advocacy group, and experts at six 
academic institutions--Boston University, the University of California-
Davis, the University of Medicine and Dentistry of New Jersey, the 
University of Minnesota, Tufts University, and Vanderbilt University. 
Second, we analyzed reports and articles by pharmaceutical industry 
financial analysts, academic researchers, consulting firms, and the 
federal government to obtain information regarding factors impacting 
drug development and potential solutions to address them. 

To supplement information from our interviews and review of studies, we 
contracted with the National Academy of Sciences (NAS) to convene a 
balanced, diverse panel of experts. At our request, these experts 
discussed key factors accounting for the drug submission and approval 
trends from 1993-2004, factors impacting new drug development, and 
potential solutions that either the pharmaceutical industry, academia, 
or the government can take to enhance new drug development. We worked 
closely with NAS to identify and select potential panelists who 
represented industry, government, advocacy groups, and academia who 
could adequately respond to our questions about the drug development 
process as well as the FDA regulatory review process. In keeping with 
NAS policy, the panelists were invited to provide their individual 
views, and the panel was not designed to build consensus on any of the 
issues discussed. After the expert panel was conducted on January 27, 
2006, in Washington, D.C., we analyzed a transcript of the panel's 
discussion to identify each expert's views on key questions. The views 
expressed by the panelists do not necessarily reflect the views of the 
organizations with which they were affiliated or the NAS. A list of the 
experts who participated in this panel is contained in appendix II. We 
also reviewed applicable laws and regulations as part of our work. We 
conducted our work from July 2005 through October 2006 in accordance 
with generally accepted government auditing standards. 

[End of section] 

Appendix II: National Academy of Sciences Expert Panel Participants: 

At our request, the National Academy of Sciences arranged an expert 
panel discussion of new drug development issues. The panel discussion 
was held on January 27, 2006, and the panelists and their affiliations 
as of the date of the panel are listed below: 

Moderator: 

Edward Holmes, M.D., Dean, School of Medicine, University of 
California, San Diego: 

Panelists: 

Jerry Avorn, M.D., Professor of Medicine at the Harvard Medical School 
and Chief of the Division of Pharmacoepidemology and Pharmacoeconomics 
at Brigham and Women's Hospital: 

Peter Corr, Ph.D., Senior-Vice President for Science and Technology at 
Pfizer Inc. 

William E. Evans, PharmD., Director and Chief Executive Officer at St 
Jude Children's Research Hospital: 

Garret A. FitzGerald, M.D., Chair of the Department of Pharmacology and 
Director of the Institute for Translational Medicine and Therapeutics 
at the University of Pennsylvania School of Medicine. 

Elaine Gallin, Ph.D., Program Director of the Medical Research Program 
at the Doris Duke Charitable Trust: 

Peter K. Honig, M.D., Senior Vice-President of Risk Management at Merck 
Research Laboratories: 

John K. Jenkins, M.D., Director of the Office of New Drugs, Center for 
Drug Evaluation and Research at the Food and Drug Administration (FDA): 

David Korn, M.D., Senior Vice-President for Biomedical and Health 
Sciences Research at the Association of American Medical Colleges: 

Jeffrey Leiden, M.D., Ph.D. President & Chief Operating Officer of the 
Pharmaceutical Products Group at Abbott Laboratories: 

John Marler, M.D., Associate Director for Clinical Trials at the 
National Institute of Neurological Diseases and Stroke at the National 
Institutes of Health: 

Musa Mayer, author, breast cancer survivor, patient advocate, patient 
representative to the FDA's Oncologic Drugs Advisory Committee, and 
patient consultant to the FDA's Cancer Drug Development Program: 

Suzanne Pattee, J.D., Vice-President of Public Policy & Patient Affairs 
at the Cystic Fibrosis Foundation: 

Cecil Pickett, Ph.D., President of the Schering-Plough Research 
Institute: 

[End of section] 

Appendix III: Comments from the Department of Health and Human 
Services: 

Office of the Assistant Secretary for Legislation: 
Department Of Health & Human Services: 
Washington, D.C. 20201: 

Oct 20 220206: 

Leslie G. Aronovitz: 
Director, Health Care: 
U.S. Government Accountability Office: 
Washington, DC 20548: 

Dear Ms. Aronovitz: 

The Department of Health and Human Services has reviewed the U.S. 
Government Accountability Office's (GAO) draft report entitled, "New 
Drug Development: Science, Business, Regulatory and Intellectual 
Property Issues Have Hampered Drug Development Efforts"(GAO 07-49) and 
is providing general and technical comments. We look forward to working 
with GAO on these issues. 

The Department appreciates the opportunity to comment on this draft 
report before its publication. 

Sincerely, 

Signed by: 

Vincent J. Ventimilgia: 
Assistant Secretary for Legislation: 

General Comments Of The Department Of Health And Human Services On The 
Government Accountability Office's Draft Report Entitled, "New Drug 
Development: Science, Business, Regulatory And Intellectual Property 
Issues Have Hampered Drug Development Efforts" (GAO 07-49): 

HHS Comments: 

Under "What GAO Found" on the summary page, the second to last sentence 
in the first full paragraph beginning on page 4, and the second 
sentence of the first paragraph on page 21, reference is made to FDA 
approving about 80% of the NDAs submitted. The concept is true, but it 
is not clear enough that that is an "eventual" outcome and not the 
"initial" (i.e., first cycle outcome). FDA recommends that it be 
clarified that FDA eventually approves about 80% of the NDAs submitted 
ed. Additionally, actual data show 76% approval of the NDAs submitted. 

On page 3, footnote 4 explains why FDA was only able to give GAO all of 
the data for the cohorts through 2004 for the report. The explanation 
there could be misleading and lead some to conclude that FDA simply is 
not very good at tracking. It should more clearly explain that 2004 was 
the most recent submission cohort where all the applications had gone 
though at least one review cycle by the time of the data request. 

On page 9, the criteria for priority review are paraphrased. Actual 
criteria should be cited rather than paraphrased, The first complete 
sentence on page 9 should be changed to read as follows: "Because anew 
molecular entity is considered an active moiety that has not previously 
been approved (either as the parent compound or as a salt, ester or 
derivative of the parent compound) in the United States for use in a 
drug product either as a single ingredient or as part of a combination, 
industry analysts and FDA generally consider them innovative." 

On page 9, characterization of standard NDAs as "those with little or 
no therapeutic potential" is misleading. For example, a new 'statin' 
would probably be a standard unless they had data showing they were 
superior on a critical endpoint, even though it likely has the same 
therapeutic potential as other statins, which is very large: 

On page 11, in the first full paragraph, characterization of what may 
be n a resubmission to an NDA should note that the resubmission often 
contains new data (studies) to address FDA concerns. 

On page 17, Table 1 is misleading. NDA reviews are ranked on the 
potential innovation of new products based on our chemical and priority 
coding. FDA does not agree that a standard NME should be ranked as more 
innovative than a priority non-NME. A standard NME could be the new 
statin mentioned previously, while a priority non-NME could be a new 
delivery system for an already approved drug that makes the product 
much more effective or safe or significantly improve; compliance. Being 
an NME in and of itself does not mean innovation. Even with respect to 
the chemical nature of an NME, often the NME is simply a minor 
modification to an existing product, or it can even be a product of an 
already approved product. The order of NDA submission types should be 
ranked from most innovative to least innovative in the following order: 

Priority NME: 
Priority non-NME: 
Standard NME: 
Standard non-NME: 

On pages 32-33, the report suggests that FDA is increasing the data  
requirements for approval, and that FDA are also asking for longer more 
complex trials. For some disease states, this may be true, but in many 
cases the increased amount of data submitted in the NDA is actually 
driven by the sponsor in order to support new claims or to better 
position their product relative to existing products. Balancing 
information should be included to clarify that it is not just FDA 
requests and requirements that can increase the size of applications. 

On page 5, in the first full paragraph, line 15, GAO references a 
suggest on to expedite the drug review process by "restructuring 
regulation of the drug review process to allow for conditional approval 
of drugs for therapeutic areas that currently lack effective treatments 
based on shorter clinical trials using fewer numbers of patients." 
Implementing such a suggestion might (would?) require statutory change: 

On page 9, first paragraph, lines 9-10, the phrase "Those with little 
or no therapeutic potential, compared to existing products,..." should 
be changed to read "Those with no substantial therapeutic difference 
from existing products..." 

On page 10, first paragraph, lines 5-6, the phrase "...completing its 
review of applications." should be changed to read "...completing its 
review of a certain percentage of applications..." 

On page 38, the first full bullet references a suggestion to implement 
an `expedited regulatory process using conditional approval to decrease 
the time needed to develop" new drugs. FDA would need statutory change 
for this proposed expedited process. 

[End of section] 

Appendix IV: GAO Contacts and Staff Acknowledgments: 

GAO Contact: 

Leslie G. Aronovitz, (312) 220-7600 or a [Hyperlink, 
aronovitzl@gao.gov] ronovitzl@gao.gov: 

Acknowledgments: 

In addition to the contact named above, Geraldine Redican-Bigott, 
Assistant Director; Shirin Hormozi; Julian Klazkin; David Lichtenfeld; 
and Stephen Ulrich made major contributions to this report. 

(290476): 

FOOTNOTES 

[1] A drug sponsor is the person or entity who assumes responsibility 
for the marketing of a new drug, including responsibility for complying 
with applicable provisions of laws, such as the Federal Food, Drug, and 
Cosmetic Act and related regulations. The sponsor is usually an 
individual, partnership, corporation, government agency, manufacturer, 
or scientific institution. 

[2] For example, see FDA, Innovation or Stagnation: Challenge and 
Opportunity on the Critical Path to New Medical Products (March 2004). 

[3] See FDA, Improving Innovation in Medical Technology: Beyond 2002 
(Jan. 31, 2003) and FDA, Innovation or Stagnation: Challenge and 
Opportunity on the Critical Path to New Medical Products (March 2004). 

[4] PhRMA represents pharmaceutical research and biotechnology 
companies. 

[5] We obtained PhRMA's data for this period to correspond with data we 
obtained from FDA. In 1992, FDA implemented a new system for 
classifying NDAs, and in 1993, specified time-frame goals for reviewing 
NDAs were established. We therefore obtained data beginning with 1993 
to generally correspond to these changes, and requested data through 
2004, which was the most recent year with a complete set of NDA 
submission data at the time of our request. 

[6] Real growth reflects growth after the effects of inflation are 
removed. 

[7] Drugs studied under INDs are compounds that are under development 
and essentially provide the pipeline of drugs that ultimately become 
the subjects of NDAs that are submitted to FDA for approval. 

[8] There are two classes of INDs--commercial and noncommercial. 
Commercial INDs are submitted primarily by companies whose ultimate 
goal is to submit an NDA to obtain marketing approval for a new 
product. Noncommercial INDs are filed for noncommercial research 
purposes. For example, a physician might submit a research IND to study 
potential medicinal uses for an unapproved drug. In this report, all 
references to INDs refer to commercial INDs. 

[9] For more information on the FDA review and approval process, see 
for example, GAO, Food and Drug Administration: Effect of User Fees on 
Drug Approval Times, Withdrawals, and Other Agency Activities, GAO-02-
958 (Washington D.C.: September 17, 2002). 

[10] FDA classifies NDAs into seven chemical types. These 
classifications are (1) NME, (2) new salt of previously approved drug 
(not a new molecular entity), (3) new formulation of previously 
approved drug (not a new salt or a new molecular entity), (4) new 
combination of two or more drugs, (5) already marketed drug product - 
duplication (i.e., new manufacturer), (6) new indication (claim) for 
already marketed drug (includes switch in marketing status from 
prescription to over the counter), and (7) already marketed drug 
product--no previously approved NDA--for example, according to an FDA 
official, a drug marketed prior to the creation of FDA, such as 
aspirin. 

[11] FDA's Manual of Policies and Procedures notes that the priority 
designation is intended to direct overall attention and resources to 
the evaluation of applications that have the potential for providing 
significant therapeutic advances as compared to "standard" 
applications. It also states that the priority determination is based 
on conditions and information available at the time the application is 
filed. It is not intended to predict a drug's ultimate value or its 
eventual place in the market. 

[12] Pub. L. No. 102-571, 106 Stat. 4491. 

[13] Biological products, or biologics, are derived from living 
sources--such as humans, animals, and microorganisms--as opposed to 
being chemically synthesized, and include vaccines and blood products. 

[14] Under PDUFA, companies pay three types of user fees to FDA-- 
application fees, establishment fees, and product fees. In most cases, 
a company seeking to market a new drug in the United States must pay an 
application fee to support the agency's review process. Generally, 
companies also pay an annual establishment fee for each facility in 
which their products subject to PDUFA are manufactured and an annual 
product fee for marketed drugs for which no generic versions are 
available. For more information on PDUFA user fees see GAO, Food and 
Drug Administration: Effect of User Fees on Drug Approval Times, 
Withdrawals, and Other Agency Activities, GAO-02-958 (Washington D.C.: 
September 17, 2002). 

[15] See: FDA, FY 2004 Performance Report to the President and the 
Congress for the Prescription Drug User Fee Act. 

[16] For example see: American Enterprise Institute-Brookings Joint 
Center, Shortening Drug Approval Times via Industry Funding of the FDA: 
Did Legislation Help or Hurt? (Feb. 16, 2005). 

[17] FDA, Improving Innovation in Medical Technology: Beyond 2002 (Jan. 
31, 2003). 

[18] FDA, Innovation or Stagnation: Challenge and Opportunity on the 
Critical Path to New Medical Products (March 2004). 

[19] We chose this time period for two reasons. First, because we 
obtained NDA data beginning with 1993 and it takes 7 years, on average, 
to successfully complete clinical trials, trends emerging from INDs 
submitted in 1986 could be reflected in NDA submission trends beginning 
in 1993. Second, 2005 was the most recent year for which we could 
obtain complete data from FDA. 

[20] Pharmaceutical Research and Manufacturers of America, 
Pharmaceutical Industry Profile 2005 (Washington, D.C.: Pharmaceutical 
Research and Manufacturers of America, 2005). Each year, PhRMA surveys 
its membership and requests information on the amount its members spent 
on research and development. According to PhRMA, these expenses include 
both domestic expenses and expenses incurred abroad. Domestic expenses 
include those incurred within the United States by PhRMA member 
companies. Expenses abroad include expenses incurred outside of the 
United States by U.S.-owned PhRMA member companies and expenses 
incurred outside the United States by the U.S. divisions of foreign- 
owned PhRMA member companies. Expenses incurred outside the United 
States by the foreign divisions of foreign-owned PhRMA member companies 
are not included. We did not independently verify these amounts. 
However, these data have been repeatedly cited, and they represent the 
best available information. For example, see Kaiser Family Foundation, 
Prescription Drug Trends (October 2004). 

[21] According to our analysis of PhRMA's data, total research and 
development expenditures were 17 percent of total sales in 1993, and 
were 16 percent in 2004. 

[22] Based on our interviews with FDA officials and our review of prior 
studies, we determined there was a general consensus that the most 
important factor in assessing the innovative potential of an NDA was 
whether or not it was an NME. 

[23] FDA, Improving Innovation in Medical Technology: Beyond 2002 (Jan. 
31, 2003). 

[24] FDA provided us with this information in September 2005. 
Therefore, many of the NDAs submitted in 2003 and 2004 were still under 
review at the time of our analyses. 

[25] Because many of the applications submitted during 2003 and 2004 
were still under review at the time we performed our analyses, the 
average approval times for these years are artificially lower. 
Therefore, we did not use average approval times for these years to 
make any comparisons to earlier years. 

[26] GAO, Food and Drug Administration: Effect of User Fees on Drug 
Approval Times, Withdrawals, and Other Agency Activities, GAO-02-958 
(Washington D.C.: September 17, 2002). 

[27] Tufts Center for the Study of Drug Development, Impact Report, 
Analysis and Insight into Critical Drug Development Issues, Vol. 2 
(October 2000). 

[28] These data reflect the total number of NDAs and NDAs for NMEs 
approved annually from 1993 through 2005, and are used to show trends 
in the numbers of NDAs and NDAs for NMEs FDA approved during those 
years. 

[29] FDA Center for Drug Evaluation and Research, 1997 and 2004 Reports 
to the Nation, Improving Public Health Through Human Drugs, and FDA's 
2005 new drug approval listings on its Web site [Hyperlink, 
(http://www.fda.gov/cder/rdmt/ndaaps05cy.htm] downloaded March 3, 2006 
and [Hyperlink, http://www.fda.gov/cder/rdmt/nmecy2005.htm] downloaded 
March 3, 2006). 

[30] For example, a panelist who was an industry representative 
explained that his company had compounds in development that were 
intended to affect the central nervous system and which successfully 
entered the brains of animals during preclinical testing. However, 
after testing the drugs in clinical trials--at a cost of $10 to $12 
million a study--researchers found that the drugs did not enter the 
brain in humans. 

[31] The Association of American Medical Colleges, Food and Drug 
Administration, Center for Drug Development Science at the University 
of California San Francisco, Drug Development Science: Obstacles and 
Opportunities for Collaboration Among Academia, Industry and Government 
(January 2005). 

[32] Joseph A. DiMasi, Ronald W. Hansen, and Henry G. Grabowski, "The 
Price of Innovation: New Estimates of Drug Development Costs", Journal 
of Health Economics, Vol. 22 (2003). 

[33] Genomics is used to study how various genes interact with drug 
compounds, and high-throughput screening allows researchers to conduct 
hundreds of tests at once through a combination of modern robotics and 
other specialized laboratory hardware. 

[34] See, for example, Ajit Varki and Leon E. Rosenberg, "Emerging 
Opportunities and Career Paths for the Young Physician-Scientist", 
Nature Medicine, Vol. 8, No. 5 (May 2002). 

[35] For example, the industry consultant indicated that because 
shareholders expect large companies to develop drugs that produce 
revenues of at least $200 to $500 million per drug per year, they 
frequently stop the development of drugs not expected to meet this 
threshold. 

[36] Congress provided incentives to expedite the development of drugs 
for rare diseases with the enactment of the Orphan Drug Act in 1983, 
such as tax credits for clinical testing expenses. 26 U.S.C. § 45C. 
Although companies have been producing drugs under these provisions, 
the panelists noted that, in certain instances, the industry does not 
view these incentives as sufficient to encourage development. 

[37] For example, see Marcia Angell, The Truth About the Drug 
Companies: How They Deceive Us and What to Do About It (Random House, 
2004). 

[38] A merger occurs when two firms agree to combine and form a single 
new company. An acquisition occurs when one company purchases another 
company and establishes itself as the new owner. Examples of some of 
the largest mergers and acquisitions include Astra with Zenica (1999), 
Glaxo Wellcome with SmithKline Beecham (2000), and Pfizer with 
Pharmacia (2003). 

[39] Tufts Center for the Study of Drug Development, Impact Report, 
Vol. 5, No. 4 (July/August 2003). 

[40] Clinical research organizations contract with drug sponsors to 
implement aspects of clinical trials, such as the design of a protocol, 
selection or monitoring of investigations, evaluation of reports, site 
monitoring visits, statistical analysis, and preparation of reports to 
FDA. 

[41] Propulsid and Fen-Phen were withdrawn due to increased risk of 
potentially fatal heart problems; Rezulin was withdrawn due to 
increased risk of liver failure; and Baycol was withdrawn due to 
increased risks of potentially fatal muscle damage. 

[42] Innovation in the Pharmaceutical Sector, a Study Undertaken for 
the European Commission (Charles River Associates, London: November 
2004). 

[43] B. Hirschhorn, Understanding the Development of the Clinical Study 
Budget While Avoiding Bumps and Pitfalls (Temple University, 
Philadelphia, Pa.: 2004). 

[44] A biomarker is a physical characteristic that can be objectively 
measured, such as blood pressure. A surrogate end point is a laboratory 
measurement or a physical sign that can predict the effect of a 
medicine on a disease. In 1992, FDA issued regulations that allow for 
the accelerated approval of new drugs for serious or life-threatening 
diseases based on surrogate end points that are reasonably likely, 
based on scientific evidence, to predict clinical benefit. 21 C.F.R. § 
314.510. 

[45] FDA, Innovation or Stagnation: Challenge and Opportunity on the 
Critical Path to New Medical Products (March 2004). 

[46] The Association of American Medical Colleges, Food and Drug 
Administration, Center for Drug Development Science at the University 
of California San Francisco, Drug Development Science: Obstacles and 
Opportunities for Collaboration Among Academia, Industry and Government 
(January 2005). 

[47] FDA, Innovation or Stagnation, Critical Path Opportunities Report 
(March 2006). 

[48] Traditionally, the length of patent terms was 17 years. This was 
amended to 20 years in 1994 with the enactment of the Uruguay Round 
Agreements Act. See 35 U.S.C. § 154 (a)(2). 

[49] For example, see National Institute for Health Care Management, 
Prescription Drugs and Intellectual Property Protection, Finding the 
Right Balance Between Access and Innovation (August 2000). 

[50] This protection was added to the Federal, Food, Drug, and Cosmetic 
Act with enactment of the Drug Price Competition and Patent Term 
Restoration Act of 1984, also known as the Waxman-Hatch Act. Among 
other things, it bars FDA from approving an application to market a 
generic copy of certain drugs, for a 3-year period, if the clinical 
investigations relied upon by the applicant for approval were not 
conducted by or for the applicant, and the applicant has not been 
authorized to rely upon such studies. 21 U.S.C. § 355(c)(3)(E)(iii). 

[51] For example, see PhRMA White Paper, Delivering on the Promise of 
Pharmaceutical Innovation: The Need to Maintain Strong and Predictable 
Intellectual Property Rights (April 2002). 

[52] Although FDA has an accelerated approval process for new drugs to 
treat serious or life-threatening conditions, the suggestion of the 
panelists was made in the context of broadening this process to 
accommodate other illnesses. Under the accelerated approval process, 
drugs designed to treat serious or life threatening conditions may be 
approved conditionally, that is, the applicant may be required to 
conduct further drug studies following approval to market the drug, to 
verify and describe the drug's clinical benefits. Applicants are also 
required to submit promotional materials to FDA during specific 
timeframes. 21 U.S.C. § 356; 21 C.F.R. §§ 314.510, 314.550. 

[53] See FDA, Improving Innovation in Medical Technology: Beyond 2002 
(Jan. 31, 2003). 

[54] For example, see Kaiser Family Foundation, Prescription Drug 
Trends, (October 2004) and National Institute for Health Care 
Management, Issue Brief, Factors Affecting the Growth of Prescription 
Drugs Expenditures (July 1999). 

[55] In addition to requesting information on NDAs, we initially 
requested information on applications for biological products, which 
are derived from living sources (such as humans, animals, and 
microorganisms) as opposed to being chemically synthesized. However, 
based on the data FDA provided, there were only 60 applications over 
the 12-year period. Therefore, we determined that it would not be 
meaningful to perform trend analyses on such a small number, and we 
limited the study's scope to NDAs. 

[56] There are two classes of INDs--commercial and noncommercial. 
Commercial INDs are submitted primarily by companies whose ultimate 
goal is to submit an NDA to obtain marketing approval for a new 
product. Noncommercial INDs are filed for noncommercial research 
purposes. In this report, all references to INDs refer to commercial 
INDs. 

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